CN215464239U - Gel particle production equipment - Google Patents

Abstract

The utility model relates to gel particle production equipment which comprises a feeding bin, wherein the feeding bin is connected with one end of a pear cutter mixer, the other end of the pear cutter mixer is connected with a roller press, one end, far away from the pear cutter mixer, of the roller press is connected with a sizing machine, and the other end of the sizing machine is connected with a screening machine. The utility model directly prepares the powder raw material into a granular product meeting the requirements of users without any intermediate or additive, the granularity of the granulated product is uniform, the bulk density is obviously increased, the pollution is controlled, the waste of powder is reduced, the appearance and the fluidity of the material are improved, and the storage and the transportation are convenient.

Description

Gel particle production equipment

Technical Field

The utility model relates to gel particle production equipment, and belongs to the technical field of dry granulation.

Background

Powder granulation is a common treatment method in the production process, and the powder is granulated, so that the obtained granular product is more abundant and solid, has a finer structure, and is beneficial to subsequent production and transportation. At present, a granulating system for granulating powder is generally wet granulation, but additives are needed in the wet granulation process to influence the purity of products, and the subsequent drying is needed to waste energy. However, the existing dry granulation system has the condition of dust pollution, and the raw materials cannot be recycled, so that the raw materials are wasted, and the utilization rate of the raw materials is low.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide gel particle production equipment.

In order to achieve the purpose, the utility model is realized by the following technical scheme: the utility model provides a gel granule production facility, includes the feeding storehouse, the feeding storehouse is connected with the one end that the pear sword mixed the machine, the other end that the pear sword mixed the machine is connected with the roller press, the roller press is kept away from the one end that the pear sword mixed the machine and is connected with whole grain machine, whole grain machine's the other end and screening machine are connected.

Preferably, the pear cutter mixer comprises a mixer shell, a rotating shaft, a pear cutter, rotating blades and mixer side walls, wherein the rotating blades are arranged on the inner wall of the mixer shell, the mixer side walls are connected to two sides of the mixer shell, the rotating shaft is connected to the mixer side walls, and the rotating shaft is connected with the pear cutter;

preferably, the mixer shell comprises a first connecting through hole, a mixer feeding hole, a mixer discharging hole and a mixer shell body, the mixer shell body is provided with the first connecting through hole, the mixer feeding hole and the mixer discharging hole, the mixer feeding hole is connected with the feeding bin, and the mixer discharging hole is connected with the roller press feeding hole;

the rotating shaft comprises a first groove and a rotating shaft body, and a plurality of first grooves are formed in the rotating shaft body;

the pear cutter comprises a pear cutter connecting shaft and a pear cutter blade, the pear cutter connecting shaft is provided with the pear cutter blade, and the pear cutter connecting shaft is connected with the rotating shaft body through a first groove;

the rotating blades comprise rotating shafts and blades, the blades are fixedly connected to the rotating shafts, and the rotating shafts are connected with an external motor through first connecting through holes;

mix the machine lateral wall and include second connect the via hole and mix the machine lateral wall casing, be equipped with second connect the via hole on mixing the machine lateral wall casing, through second connect the via hole realizes that the pivot body is connected with external motor.

Preferably, the roller press comprises a roller press shell, a rolling shaft and roller press side walls, the roller press side walls are connected to two sides of the roller press shell, and the roller shaft is arranged on the inner wall of the roller press shell.

Preferably, the shell of the roller press comprises a roller press feed inlet, a roller press discharge outlet, a U-shaped feed inlet and a roller press shell, the roller press shell is provided with the roller press feed inlet and the roller press discharge outlet, the bottom of the roller press feed inlet is connected with the U-shaped feed inlet, and the roller press feed inlet is connected with the mixer discharge outlet;

the roll shaft comprises a roll shaft rotating shaft and a roll shaft body, and the two ends of the roll shaft body are fixedly connected with the roll shaft rotating shaft;

the side wall of the roller press comprises a third connecting through hole and a side wall shell of the roller press, the side wall shell of the roller press is provided with the third connecting through hole, and the connection of the roller shaft rotating shaft and the external motor is realized through the third connecting through hole.

Preferably, the number of the roll shafts is 2, and the U-shaped feed inlet is clamped between the two roll shafts.

Preferably, the granulator includes to one side antithetical couplet, connecting rod, briquetting, granulator upper cover, cutting disc, granulator lower wall, granulator shell and end antithetical couplet, be connected with to one side antithetical couplet, granulator upper cover, granulator lower wall on the granulator shell, the granulator upper cover is connected with the connecting rod, the connecting rod meshes with the roller bearing, the one end that the granulator upper cover was kept away from to the connecting rod is connected with the briquetting, be connected with cutting disc and end antithetical couplet on the granulator lower wall.

Preferably, the connecting rod comprises a connecting rod body, a connecting rod rack and a connecting rod connecting shaft, the connecting rod connecting shaft is symmetrically arranged at two ends of the connecting rod body, and the connecting rod rack is arranged on the connecting rod body;

the pressing block comprises a second groove and a pressing block body, and the pressing block body is provided with the second groove;

the upper cover of the granulator comprises a third groove and a granulator upper cover shell, the granulator upper cover shell is provided with the third groove, and the granulator upper cover shell is fixedly connected with the connecting rod connecting shaft through the third groove;

the cutting disc comprises a first through hole and a cutting disc shell, and a plurality of first through holes are formed in the cutting disc shell;

the lower disc of the granulator comprises a fourth connecting through hole and a lower disc shell of the granulator, the lower disc shell of the granulator is provided with the fourth connecting through hole, and the cutting disc shell is clamped on the fourth connecting through hole;

the granulator shell comprises a U-shaped through hole, a granulator shell body and a fifth through hole, the granulator shell body is provided with the U-shaped through hole and the fifth through hole, the granulator shell body is obliquely communicated with the granulator shell body through the U-shaped through hole, and the roller press shell body is obliquely communicated with a discharge hole of the roller press;

the bottom connector comprises a granulator discharge port and a bottom connector shell, and the bottom connector shell is provided with the granulator discharge port;

the roller comprises a roller body, roller racks and roller connecting shafts, the two sides of the roller body are symmetrically connected with the roller connecting shafts, the roller body is connected with the roller racks in an annular matrix mode, and the roller connecting shafts are connected with an external motor through fifth through holes.

Preferably, the screening machine includes connector, sieve, screening machine play feed bin and screening machine upper cover, the connector is connected with end antithetical couplet, screening machine upper cover respectively, the screening machine upper cover is connected with the sieve, the one end that the screening machine upper cover was kept away from to the sieve is connected with screening machine play feed bin.

Preferably, the screen comprises a second through hole and a screen shell, and a plurality of second through holes are formed in the screen shell;

the screening machine discharge bin comprises a screening machine discharge port and a screening machine discharge bin shell, and the screening machine discharge bin shell is provided with a screening machine discharge port;

the screening machine upper cover comprises a sixth connecting through hole and a screening machine upper cover shell, the screening machine upper cover shell is provided with the sixth connecting through hole, and the connector is connected with the screening machine upper cover shell through the sixth connecting through hole.

The utility model has the beneficial effects that:

(1) the utility model directly prepares the powder raw material into a granular product meeting the requirements of users without any intermediate or additive, the granularity of the granulated product is uniform, the bulk density is obviously increased, the pollution is controlled, the waste of powder is reduced, the appearance and the fluidity of the material are improved, and the storage and the transportation are convenient.

(2) The utility model is suitable for granulating various dry powders of chemical drugs, chemical products, soda ash, fertilizers, feeds, plastic additives, foods, cosmetics, synthetic detergents, disinfectants and the like.

Drawings

FIG. 1 is a schematic diagram of the apparatus of the present invention.

Fig. 2 is a schematic structural view of the feeding bin of the present invention.

Fig. 3 is a schematic structural view of the pearskin mixer of the present invention.

Fig. 4 is a front view of the mixer housing of the pearskin mixer of the present invention.

Fig. 5 is a cross-sectional view a-a of fig. 4 of the present invention.

FIG. 6 is a schematic view of the hinge shown in FIG. 3 according to the present invention.

Fig. 7 is a cross-sectional view of fig. 7 of the present invention.

Fig. 8 is a schematic structural view of the pear knife in fig. 3.

Fig. 9 is a schematic view of the structure of the rotary blade of fig. 3 according to the present invention.

FIG. 10 is a schematic view of the structure of the side wall of the mixer of the present invention.

Fig. 11 is a schematic view of the internal structure of the roll press of the present invention.

Fig. 12 is a schematic structural view of a roll press housing of the present invention.

Fig. 13 is a schematic view showing the structure of a roll shaft of the roll press of the present invention.

FIG. 14 is a schematic view of the side wall of the roller press of the present invention.

Fig. 15 is a schematic view of the structure of the granulator removing granulator shell according to the present invention.

Fig. 16 is a schematic structural view of the connecting rod of fig. 15 according to the present invention.

FIG. 17 is a schematic structural view of the compact of FIG. 15 according to the present invention.

FIG. 18 is a schematic view of the top cover of the granulator of FIG. 15 according to the present invention.

Fig. 19 is a schematic structural view of the cutting disk of fig. 15 according to the present invention.

FIG. 20 is a schematic view of the bottom wall of the granulator of FIG. 15 according to the present invention.

Fig. 21 is a schematic structural view of the granulator shell of fig. 15 according to the present invention.

Fig. 22 is a schematic structural view of the bottom link of fig. 15 according to the present invention.

FIG. 23 is a schematic view of the roller of FIG. 15 according to the present invention.

Figure 24 is a schematic diagram of the construction of the sizer of the present invention.

Fig. 25 is a cross-sectional view of fig. 24 in accordance with the present invention.

Fig. 26 is a schematic view of the structure of the screen of fig. 24 according to the present invention.

Fig. 27 is a schematic structural view of the discharge bin of the sieving machine of fig. 24 in accordance with the present invention.

Fig. 28 is a schematic structural view of the upper cover of the screening machine of fig. 24 according to the present invention.

In the figure: 1-a feeding bin;

2-pear cutter mixer, 21-mixer shell, 211-first connecting through hole, 212-mixer feed inlet, 213-mixer discharge outlet, 214-mixer shell, 22-rotating shaft, 221-first groove, 222-rotating shaft body, 23-pear cutter, 231-pear cutter connecting shaft, 232-pear cutter blade, 24-rotating blade, 241-rotating shaft, 242-blade, 25, mixer side wall, 251-second connecting through hole and 252-mixer side wall shell;

3-rolling machine, 31-rolling machine shell, 311-rolling machine feed inlet, 312-rolling machine discharge outlet, 313-U-shaped feed inlet, 314-rolling machine shell, 32-roll shaft, 321-roll shaft rotating shaft, 322-roll shaft body, 33-rolling machine side wall, 331-third connecting through hole and 332-rolling machine side wall shell;

4-granulator, 41-oblique joint, 42-connecting rod, 421-connecting rod body, 422-connecting rod rack, 423-connecting rod connecting shaft, 43-briquetting, 431-second groove, 432-briquetting body, 44-granulator upper cover, 441-third groove, 442-granulator upper cover shell, 45-cutting disc, 451-first through hole, 452-cutting disc shell, 46-granulator lower disc, 461-fourth connecting through hole, 462-granulator lower disc shell, 47-granulator shell, 471-U-shaped through hole, 472-granulator shell, 473-fifth through hole, 48-bottom joint, 481-granulator discharge hole, 482-bottom joint shell, 49-rolling shaft, 491-rolling shaft body, rolling rod rack rolling shaft, 492, 493-roller connecting shaft;

5-sieving machine, 51-connecting body, 52-sieving machine, 521-second through hole, 522-sieving machine shell, 53-sieving machine discharging bin, 531-sieving machine discharging hole, 532-sieving machine discharging bin shell, 54-sieving machine upper cover, 541-sixth connecting through hole and 542-sieving machine upper cover shell.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the utility model easy to understand, the utility model is further described with the specific embodiments.

Referring to fig. 1, a gel particle production facility, including feeding storehouse 1, pear sword mix machine 2, roller press 3, whole grain machine 4 and screening machine 5, feeding storehouse 1 is connected with the one end that the pear sword mixes machine 2, and the other end that the pear sword mixed machine 2 is connected with roller press 3, and the one end that the pear sword mixed machine 2 was kept away from to roller press 3 is connected with whole grain machine 4, and the other end of whole grain machine 4 is connected with screening machine 5.

Referring to fig. 3, a mixer sidewall 25 is connected to both sides of the mixer housing 21, a rotary shaft 22 is connected to the mixer sidewall 25, and the rotary shaft 22 is connected to the pear cutter 23.

Referring to fig. 4 and 5, the mixer housing 214 is provided with a first connecting through hole 211, a mixer inlet 212 and a mixer outlet 213, the mixer inlet 212 is connected with the feeding bin 1, and the mixer outlet 213 is connected with the roller press inlet 311;

referring to fig. 6 and 7, the shaft body 222 is provided with a plurality of first grooves 221;

referring to fig. 8, a pear cutter blade 232 is disposed on the pear cutter connecting shaft 231, and the pear cutter connecting shaft 231 is connected to the rotating shaft body 222 through the first groove 221;

referring to fig. 9, a blade 242 is fixedly connected to a rotating shaft 241, the rotating shaft 241 is connected to an external motor through a first connecting through hole 211, and the external motor drives the rotating shaft 241 to rotate, so as to mix materials;

referring to fig. 10, a second connecting through hole 251 is formed in the side wall casing 252 of the mixing machine, the rotating shaft body 222 is connected to the external motor through the second connecting through hole 251, and the rotating shaft body 222 is rotated by the external motor, so as to drive the blades 242 to rotate, and further achieve the mixing of the materials.

Referring to fig. 11, the roll press housing 21 is connected at both sides thereof with roll press side walls 33, and the roll shaft 32 is provided on the inner wall of the roll press housing 31.

Referring to fig. 12, a shell 314 of the roller press is provided with a roller press feed inlet 311 and a roller press discharge outlet 312, the bottom of the roller press feed inlet 311 is connected with a U-shaped feed inlet 313, the roller press feed inlet 311 is connected with a mixer discharge outlet 213, the number of the roller shafts 32 is 2, the U-shaped feed inlet 313 is clamped between the two roller shafts, when a material enters the roller press 2 from the U-shaped feed inlet 313, the U-shaped feed inlet 313 is designed to avoid dispersion of the material, and simultaneously, the two roller shafts rotate in opposite directions, so that the incoming material can be rolled and flaked in a centralized manner, and the rolled and flaked product is sent to the granulator 4 through the roller press discharge outlet 312;

referring to fig. 13, both ends of the roller shaft body 322 are fixedly connected with the roller shaft rotating shafts 321;

referring to fig. 13, a third connecting through hole 331 is formed in the side wall housing 332 of the roller press, and the connection between the roller shaft 321 and the external motor is realized through the third connecting through hole 331.

Referring to fig. 15, a cross-coupling 41, a top cover 44 and a bottom plate 46 are connected to a granulator housing 47, a connecting rod 42 is connected to the top cover 44, the connecting rod 42 is engaged with a roller 49, a pressing block 43 is connected to one end of the connecting rod 42 away from the top cover 44, and a cutting plate 45 and a bottom coupling 48 are connected to the bottom plate 46.

Referring to fig. 16, the connecting rod connecting shafts 423 are symmetrically disposed at both ends of the connecting rod body 421, and the connecting rod body 421 is provided with connecting rod racks 422;

referring to fig. 17, a second groove 431 is provided on the pressing block body 431;

referring to fig. 18, a third groove 441 is formed on the granulator upper cover housing 442, and the granulator upper cover housing 442 is fixedly connected to the connecting rod connecting shaft 423 through the third groove 441;

referring to fig. 19, the cutting tray housing 452 is provided with a plurality of first through holes 451, and when the sheet-shaped product is moved from the roll press 3 to the cutting tray housing 452, the pressing block 43 descends to press the product, and the product is formed into pellets through the first through holes 451;

referring to fig. 20, a lower disc shell 462 of the granulator is provided with a fourth connecting through hole 461, and the cutting disc shell 452 is clamped on the fourth connecting through hole 461;

referring to fig. 21, a U-shaped through hole 471 and a fifth through hole 473 are provided on the granulator housing 472, the oblique coupling 41 is connected to the granulator housing 472 through the U-shaped through hole 471, and the oblique coupling 41 is connected to the roller press housing 314 through the roller press discharge port 312;

referring to fig. 22, a bottom coupling housing 482 is provided with a granulator outlet 481;

referring to fig. 23, two sides of the roller body 491 are symmetrically connected with roller connecting shafts 493, the roller body 491 is connected with roller racks 492 in an annular matrix manner, the roller connecting shafts 493 are connected with an external motor through fifth through holes 473, and the pressing block 43 moves up and down through the meshing of the roller racks 492 and the connecting rod racks 422.

Referring to fig. 24 and 25, the connecting body 51 is respectively connected with the bottom coupling 48 and the screening machine upper cover 54, the screening machine upper cover 54 is connected with the screen 52, and one end of the screen 52 far away from the screening machine upper cover 54 is connected with the screening machine discharging bin 53.

Referring to fig. 26, the screen housing 522 is provided with a plurality of second through holes 521;

referring to fig. 27, a screening machine discharge port 531 is provided on the screening machine discharge bin housing 532;

referring to fig. 28, a sixth connection through hole 541 is formed in the sieving machine upper cover housing 542, and the connector 51 is connected to the sieving machine upper cover housing 542 through the sixth connection through hole 541.

The working principle is as follows:

powder enters the whole device from the feeding bin 1, is conveyed to the pear cutter mixer 2 through the feeding bin 1, and respectively drives the rotating shaft body 222 and the rotating shaft 241 to rotate under the action of the motor, so that the rotation of the rotating blades 24 and the pear cutter 23 is realized, and the powder is further fully mixed in the pear cutter mixer 2;

the fully mixed powder enters the roller press 3 through a discharge hole 213 of the mixer, and the motor drives the roller shaft 32 to rotate, so that the powder is rolled into sheets;

the flaky materials enter the granulator 4 through the inclined connection 41, the motor drives the roller 49 to rotate, the granulator upper cover 44 is not fixedly connected with the granulator shell 47, the pressing block 43, the connecting rod 42 and the granulator upper cover 44 are fixedly connected, and the roller 49 is meshed with the connecting rod 42, so that the pressing block 43, the connecting rod 42 and the granulator upper cover 44 move up and down, the flaky materials are flatly laid on the cutting disc 45, when the pressing block 43 moves downwards, the flaky materials are extruded and cut into granules under the action of the cutting disc 45;

the granular materials enter the sieving machine 5 through the bottom coupling 48, the powder raw materials are sieved out from the sieve 52 and collected, and are returned to the feeding bin 1 for reuse, and the granular materials are discharged through the sieving machine discharging bin 53.

While there have been shown and described what are at present considered the fundamental principles and essential features of the utility model and its advantages, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The utility model provides a gel granule production facility, its characterized in that, includes feeding storehouse (1), feeding storehouse (1) is connected with the one end that the pear sword mixes machine (2), the other end that the pear sword mixes machine (2) is connected with roller press (3), roller press (3) are kept away from the one end that the pear sword mixes machine (2) and are connected with whole grain machine (4), the other end and the screening machine (5) of whole grain machine (4) are connected.

2. The gel particle production equipment according to claim 1, wherein the pear cutter mixer (2) comprises a mixer housing (21), a rotating blade (24) is arranged on the inner wall of the mixer housing (21), mixer side walls (25) are connected to two sides of the mixer housing (21), a rotating shaft (22) is connected to each mixer side wall (25), and the rotating shaft (22) is connected with the pear cutter (23);

3. the gel particle production equipment according to claim 2, wherein the mixer housing (21) comprises a mixer housing (214), the mixer housing (214) is provided with a first connecting through hole (211), a mixer inlet (212) and a mixer outlet (213), the mixer inlet (212) is connected with the feeding bin (1), and the mixer outlet (213) is connected with the roller press inlet (311);

the rotating shaft (22) comprises a rotating shaft body (222), and a plurality of first grooves (221) are formed in the rotating shaft body (222);

the pear cutter (23) comprises a pear cutter connecting shaft (231), pear cutter blades (232) are arranged on the pear cutter connecting shaft (231), and the pear cutter connecting shaft (231) is connected with the rotating shaft body (222) through a first groove (221);

the rotating blade (24) comprises a rotating shaft (241), the rotating shaft (241) is fixedly connected with a blade (242), and the rotating shaft (241) is connected with an external motor through a first connecting through hole (211);

mix quick-witted lateral wall (25) including mixing quick-witted lateral wall casing (252), be equipped with second connect the through-hole (251) on mixing quick-witted lateral wall casing (252), through second connect the through-hole (251) realize that pivot body (222) are connected with external motor.

4. The apparatus for producing gel particles as claimed in claim 1, wherein said roller press (3) comprises a roller press housing (31), and a roller press side wall (33) is connected to both sides of said roller press housing (21), and a roller shaft (32) is provided on the inner wall of said roller press housing (31).

5. The gel particle production equipment according to claim 4, wherein the roller press housing (31) comprises a roller press housing (314), a roller press feed inlet (311) and a roller press discharge outlet (312) are arranged on the roller press housing (314), a U-shaped feed inlet (313) is connected to the bottom of the roller press feed inlet (311), and the roller press feed inlet (311) is connected with the mixer discharge outlet (213);

the roll shaft (32) comprises a roll shaft body (322), and two ends of the roll shaft body (322) are fixedly connected with roll shaft rotating shafts (321);

the side wall (33) of the roller press comprises a side wall shell (332) of the roller press, a third connecting through hole (331) is formed in the side wall shell (332) of the roller press, and the connection between the roller shaft rotating shaft (321) and an external motor is realized through the third connecting through hole (331).

6. A gel particle production apparatus according to claim 5 wherein said number of rollers (32) is 2 and said U-shaped feed opening (313) is captured between two rollers (32).

7. A gel particle production apparatus as claimed in claim 1, wherein said granulator (4) comprises a granulator housing (47), said granulator housing (47) is connected with a diagonal coupling (41), a granulator upper cover (44) and a granulator lower disc (46), said granulator upper cover (44) is connected with a connecting rod (42), said connecting rod (42) is engaged with a roller (49), one end of said connecting rod (42) far from said granulator upper cover (44) is connected with a pressing block (43), and said granulator lower disc (46) is connected with a cutting disc (45) and a bottom coupling (48).

8. The gel particle production apparatus according to claim 7, wherein the connecting rod (42) comprises a connecting rod body (421), connecting rod connecting shafts (423) are symmetrically arranged at two ends of the connecting rod body (421), and connecting rod racks (422) are arranged on the connecting rod body (421);

the pressing block (43) comprises a pressing block body (431), and a second groove (431) is formed in the pressing block body (431);

the granulator upper cover (44) comprises a granulator upper cover shell (442), a third groove (441) is formed in the granulator upper cover shell (442), and the granulator upper cover shell (442) is fixedly connected with the connecting rod connecting shaft (423) through the third groove (441);

the cutting disc (45) comprises a cutting disc shell (452), and a plurality of first through holes (451) are formed in the cutting disc shell (452);

the lower plate (46) of the granulator comprises a lower plate shell (462) of the granulator, a fourth connecting through hole (461) is formed in the lower plate shell (462) of the granulator, and the cutting plate shell (452) is clamped on the fourth connecting through hole (461);

the granulator shell (47) comprises a granulator shell body (472), a U-shaped through hole (471) and a fifth through hole (473) are formed in the granulator shell body (472), the inclined connection (41) is connected with the granulator shell body (472) through the U-shaped through hole (471), and the inclined connection (41) is connected with the roller press shell (314) through a roller press discharge hole (312);

the bottom coupling (48) comprises a bottom coupling shell (482), and a discharging hole (481) of the granulator is formed in the bottom coupling shell (482);

the roller (49) comprises a roller body (491), two sides of the roller body (491) are symmetrically connected with roller connecting shafts (493), an annular matrix on the roller body (491) is connected with roller racks (492), and the roller connecting shafts (493) are connected with an external motor through fifth through holes (473).

9. The gel particle production equipment according to claim 1, wherein the screening machine (5) comprises a connecting body (51), the connecting body (51) is respectively connected with the bottom coupling (48) and the screening machine upper cover (54), the screening machine upper cover (54) is connected with the screen (52), and one end of the screen (52) far away from the screening machine upper cover (54) is connected with the screening machine discharging bin (53).

10. A gel particle production apparatus as claimed in claim 9 wherein said screen (52) comprises a screen housing (522), said screen housing (522) being provided with a plurality of second through holes (521);

the screening machine discharging bin (53) comprises a screening machine discharging bin shell (532), and a screening machine discharging port (531) is formed in the screening machine discharging bin shell (532);

the screening machine upper cover (54) comprises a screening machine upper cover shell (542), a sixth connecting through hole (541) is formed in the screening machine upper cover shell (542), and the connecting body (51) is connected with the screening machine upper cover shell (542) through the sixth connecting through hole (541).

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